Registration of device characteristics with optical layer for use in establishing connections through an optical network

ABSTRACT

Disclosed are, inter alia, methods, apparatus, computer-storage media, mechanisms, and means associated with registration of optical device characteristics of optical network devices with an optical control layer of the optical network for use in establishing compatible connections through the optical network. Especially end network devices and internal network optical devices that regenerate the optical signal register their communication capabilities of their optical interfaces with the optical control layer of an optical network. This registration allows a light path to be established through the optical network which is compatible with the registered capabilities. The optical control layer may be centralized in an optical layer server and/or distributed among optical devices in the optical network, such as on control processors in multiple, optical layer devices.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No.12/355,921, filed Jan. 19, 2009, which is hereby incorporated byreference in its entirety.

TECHNICAL FIELD

The present disclosure relates generally to communications and computersystems, especially routers, packet switching systems, and other networkdevices.

BACKGROUND

The communications industry is rapidly changing to adjust to emergingtechnologies and ever increasing customer demand. This customer demandfor new applications and increased performance of existing applicationsis driving communications network and system providers to employnetworks and systems having greater speed and capacity (e.g., greaterbandwidth). Dense wavelength-division multiplexing (DWDM) is being usedto carry more traffic over a single optical fiber. As the name suggests,this technology transmits multiple signals simultaneously at differentwavelengths on a same fiber. In one application, DWDM technology isbeing used to expand the bandwidth capacity of existing backbonenetworks. In order to communicate between optical devices, a light pathis configured through an optical network between the optical devices,with this light path possibly including an optical regenerator.

BRIEF DESCRIPTION OF THE DRAWINGS

The appended claims set forth the features of the invention withparticularity. The invention, together with its advantages, may be bestunderstood from the following detailed description taken in conjunctionwith the accompanying drawings of which:

FIG. 1 illustrates a network operating according to one embodiment;

FIG. 2 illustrates a network operating according to one embodiment;

FIG. 3 illustrates an example system or component used in oneembodiment;

FIG. 4A illustrates a process performed in one embodiment;

FIG. 4B illustrates a process performed in one embodiment;

FIG. 5A illustrates a process performed in one embodiment; and

FIG. 5B illustrates a process performed in one embodiment.

DESCRIPTION OF EXAMPLE EMBODIMENTS

1. Overview

Disclosed are, inter alia, methods, apparatus, computer-storage media,mechanisms, and means associated with registration of optical devicecharacteristics of optical network devices with an optical control layerof the optical network for use in establishing compatible connectionsthrough the optical network. In one embodiment, these network devicesinclude, but are not limited to, packet switching devices, opticalregenerators and/or other devices within the optical network orotherwise connected to the optical network. In one embodiment, theoptical control layer includes, or simply is, an optical layer server(e.g., including a optical path computation engine and/or opticalnetwork management system). In one embodiment, the optical control layeris distributed among devices within the optical network, such as oncontrol processors in multiple, optical layer devices. In oneembodiment, the optical control layer includes both the distributedoptical control layer and one or more optical layer servers.

2. Description

Embodiments described herein include various elements and limitations,with no one element or limitation contemplated as being a criticalelement or limitation. Each of the claims individually recites an aspectof the invention in its entirety. Moreover, some embodiments describedmay include, but are not limited to, inter alia, systems, networks,integrated circuit chips, embedded processors, ASICs, methods, andcomputer-readable media containing instructions. One or multiplesystems, devices, components, etc. may comprise one or more embodiments,which may include some elements or limitations of a claim beingperformed by the same or different systems, devices, components, etc.The embodiments described hereinafter embody various aspects andconfigurations within the scope and spirit of the invention, with thefigures illustrating exemplary and non-limiting configurations. Note,computer-readable media and means for performing methods and processingblock operations are disclosed and are in keeping with the extensiblescope and spirit of the invention. Moreover, nothing described orreferenced in this document is admitted as prior art to this applicationunless explicitly so stated.

The steps, connections, and processing of signals and informationillustrated in the figures, including, but not limited to any block andflow diagrams and message sequence charts, may typically be performed inthe same or in a different serial or parallel ordering and/or bydifferent components and/or processes, threads, etc., and/or overdifferent connections and be combined with other functions in otherembodiments, unless this disables the embodiment or a sequence isexplicitly or implicitly required (e.g., for a sequence of read thevalue, process said read value—the value must be obtained prior toprocessing it, although some of the associated processing may beperformed prior to, concurrently with, and/or after the read operation).

The term “one embodiment” is used herein to reference a particularembodiment, wherein each reference to “one embodiment” may refer to adifferent embodiment, and the use of the term repeatedly herein indescribing associated features, elements and/or limitations does notestablish a cumulative set of associated features, elements and/orlimitations that each and every embodiment must include, although anembodiment typically may include all these features, elements and/orlimitations. In addition, the terms “first,” “second,” etc. aretypically used herein to denote different units (e.g., a first element,a second element). The use of these terms herein does not necessarilyconnote an ordering such as one unit or event occurring or coming beforeanother, but rather provides a mechanism to distinguish betweenparticular units. Moreover, the phrases “based on x” and “in response tox” are used to indicate a minimum set of items “x” from which somethingis derived or caused, wherein “x” is extensible and does not necessarilydescribe a complete list of items on which the operation is performed,etc. Additionally, the phrase “coupled to” is used to indicate somelevel of direct or indirect connection between two elements or devices,with the coupling device or devices modifying or not modifying thecoupled signal or communicated information. Moreover, the term “or” isused herein to identify a selection of one or more, including all, ofthe conjunctive items. Additionally, the transitional term “comprising,”which is synonymous with “including,” “containing,” or “characterizedby,” is inclusive or open-ended and does not exclude additional,unrecited elements or method steps.

Disclosed are, inter alia, methods, apparatus, computer-storage media,mechanisms, and means associated with registration of optical devicecharacteristics of optical network devices with an optical control layerof the optical network for use in establishing compatible connectionsthrough the optical network. In one embodiment, these network devicesinclude, but are not limited to, packet switching devices, opticalregenerators and/or other devices within the optical network orotherwise connected to the optical network. In one embodiment, theoptical control layer includes, or simply is, an optical layer server(e.g., including a optical path computation engine and/or opticalnetwork management system). In one embodiment, the optical control layeris distributed among devices within the optical network, such as oncontrol processors in multiple, optical layer devices. In oneembodiment, the optical control layer includes both the distributedoptical control layer and one or more optical layer servers.

One embodiment includes an apparatus, comprising: a plurality of opticalinterfaces, each configured for coupling with an optical fiber forcommunicating information using wavelength-division multiplexing (WDM)with an optical network, with each of the plurality of opticalinterfaces being characterized by a plurality of communicationcapabilities of its optical transmitter or receiver, with saidcommunication capabilities including optical transmissioncharacteristics for said optical transmitter and optical receivingcharacteristics for said optical receiver; and a controller configuredto inform an optical control layer, outside the apparatus, of saidcommunication capabilities of each of its said one or more opticalinterfaces for use in configuring the optical network to routecompatible signals with the apparatus through the optical network.

In one embodiment, at least one of the plurality of optical interfaceshas configurable alternative values of said communication capabilities;wherein the apparatus is configured to receive an identification ofparameters according to said configurable alternative values from theoptical control layer outside the apparatus; and wherein the apparatusis configured to configure said at least one of said optical interfacesto operate according to said received parameters for communicating overat least one of said optical fibers. In one embodiment, said opticalcontrol layer is distributed among a plurality of optical appliances inthe optical network. In one embodiment, the apparatus receives theidentification of parameters according to said configurable alternativevalues from the optical control layer in one of the plurality of opticalappliances in the optical network. In one embodiment, said opticalcontrol layer includes a centralized optical layer server. In oneembodiment, said communication capabilities that are said informed tothe optical control layer for the optical transmitter include a range oftransmitted power and frequency characteristics. In one embodiment, saidcommunication capabilities that are said informed to the optical controllayer for the optical transmitter include bit rate, modulation format,forward error correction type, signal format, and frame formatcharacteristics. In one embodiment, said communication capabilities thatare said informed to the optical control layer for the optical receiverinclude a range of valid input power and supported wavelengthcharacteristics. In one embodiment, said communication capabilities thatare said informed to the optical control layer for the optical receiverinclude bit rate, modulation format, forward error correction type,signal format, and frame format characteristics. In one embodiment, thecontroller is configured to inform the optical control layer of saidcommunication capabilities of both said optical transmitter and receiverof each of its said one or more optical interfaces for use inconfiguring the optical network to route compatible signals with theapparatus through the optical network. In one embodiment, the apparatusis a router appliance. In one embodiment, the apparatus includes anoptical regenerator coupled to at least two of the plurality of opticalinterfaces.

One embodiment includes an apparatus, comprising: an optical interfaceconfigured for coupling with one or more optical fibers forcommunicating information using wavelength-division multiplexing (WDM)with an optical network, with each of said one or more opticalinterfaces being characterized by a plurality of communicationcapabilities of its optical transmitter or receiver, with saidcommunication capabilities including optical layer transmissioncharacteristics for an optical transmitter and optical layer receivingcharacteristics for an optical receiver; and a controller configured toinform an optical layer server, external to the apparatus, of saidcommunication capabilities of each of its said one or more opticalinterfaces for use in configuring the optical layer network to routecompatible signals with the apparatus through the optical layer network.

In one embodiment, at least one of said optical interfaces hasconfigurable alternative values of said communication capabilities;wherein the apparatus is configured to receive an identification ofparameters according to said configurable alternative values from theoptical layer server; and wherein the apparatus is configured toconfigure said at least one of said optical interfaces to operateaccording to said received parameters for communicating over at leastone of said optical fibers. In one embodiment, the optical layer serveris configured to perform network management functions. In oneembodiment, the optical server is configured to perform pathcomputations within the optical network based on optical characteristicsregistered with it including said communication capabilities of said oneor more optical interfaces.

One embodiment includes an apparatus, comprising: one or more opticalnetwork interfaces coupled to an optical network including a pluralityof network appliances, wherein each of the plurality of networkappliances includes one or more particular optical interfaces configuredfor coupling with the optical network for communicating informationusing wavelength-division multiplexing (WDM), with each of said one ormore particular optical interfaces being characterized by a plurality ofcommunication capabilities of its optical transmitter or receiver, withsaid communication capabilities including optical layer transmissioncharacteristics for an optical transmitter and optical layer receivingcharacteristics for an optical receiver; and one or more processors andmemory configured, based on received communication capabilities of saidoptical interfaces of the plurality of network devices, to determinecompatible light paths through the optical network opticallycommunicatively coupling pairs of network devices of the plurality ofnetwork devices, and to cause the optical network to provide saiddetermined compatible light paths.

In one embodiment, said configuring of the optical network includesdetermining one or more optical network devices within the opticalnetwork compatible with said communication capabilities of twoparticular network devices of the plurality of network devices; and inresponse to said determination of said compatible one or more opticalnetwork devices, including at least one of said compatible one or moreoptical network devices in one of said compatible light paths betweensaid two particular network devices. In one embodiment, said compatibleone or more optical network devices includes at least one opticalregenerator. In one embodiment, at least one of said two particularnetwork devices has configurable alternative values of saidcommunication capabilities; and wherein the apparatus is configured tosend an identification of parameters according to said configurablealternative values to said at least one of said two particular networkdevices for configuring at least one of its said one or more opticalinterfaces according to said parameters for communicating over at leastone of said optical fibers. In one embodiment, said communicationcapabilities that are said received from each of the plurality ofnetwork devices include one or more of a group of communicationcapabilities consisting of: range of transmitted power, range of validinput power, and supported wavelength characteristics.

One embodiment includes a method performed by an optical control layerof an optical network, the method comprising: receiving, from eachparticular network device of a plurality of network devicescommunicatively coupled with the optical network, a registration of aplurality of selectable communication capabilities of the opticaltransmitters and optical receivers for communicating information by saidparticular network device over the optical network usingwavelength-division multiplexing (WDM), with said communicationcapabilities including optical layer transmission characteristics for anoptical transmitter and optical layer receiving characteristics for anoptical receiver; selecting compatible communications capabilities forcommunicating with each other over the optical network of two particularnetwork devices of the plurality of network devices from said registeredselectable communication capabilities of said two particular networkdevices; and communicating respective said compatible communicationscapabilities to each of said two particular network devices forconfiguration by said two particular network devices for communicatingover the optical network.

One embodiment includes causing the optical network to provide acompatible light path through the optical network between said twoparticular network devices. In one embodiment, said causing the opticalnetwork to provide a compatible light path through the optical networkbetween said two particular network devices includes causing the opticalnetwork to provide said compatible light path through an opticalregenerator. In one embodiment, the plurality of network devicesincludes the optical regenerator; with the method including: selectingcompatible communications capabilities of the optical regenerator fromsaid registered selectable communication capabilities of the opticalregenerator for said two particular network devices to communicate overthe optical network.

Expressly turning to the figures, FIG. 1 illustrates an example network100 operating according to one or more embodiments. Shown are opticalnetwork 101 and two network devices 111 and 112 configured forcommunicating between themselves over optical network 101. Opticalnetwork 101 typically includes optical fibers and other opticalequipment, such as, but not limited to amplifiers, multiplexers,switches, optical regenerators, etc. Examples of network devices 111 and112 include, but are not limited to, packet switching devices (e.g.,routers, bridges).

As show, network devices 111 and 112 are configured to register/informthe optical control layer of optical network 101 of their respectivecommunication capabilities/characteristics for use by optical controllayer of optical network 101 in determining compatible light pathsthrough optical network 101. Additionally, one or more optical networkelements register their respective communicationcapabilities/characteristics for use by optical control layer of opticalnetwork 101 in determining compatible light paths through opticalnetwork 101. After having registered their optical characteristics,including possibly registering alternative characteristics, the opticalcontrol layer can determine compatible light paths through the opticalnetwork, and inform the optical devices of optical characteristics touse in transmitting and/or receiving data. The list of communicationscapabilities that are possibly registered is extensible, and maytypically include, but is not limited to, range of transmitted power,frequency characteristics, range of valid input power, supportedwavelength characteristics, optical layer output power, wavelengthcharacteristics, frequency characteristics, bit rate, modulation format,forward error correction type, signal format, and frame formatcharacteristics. Additionally, a device may register alternativessupported by the device, possibly identifying default characteristics,and may possibly negotiate with the optical control layer of opticalnetwork 101 of optical characteristics to use in communicating over alight path through optical network 101. The operation of one embodimentwill be described in relation to each of the flow diagrams of FIGS. 4A,4B, 5A and 5B described hereinafter.

FIG. 2 illustrates an example network 200 operating according to one ormore embodiments. Shown are optical network appliances (e.g., devices)221, 222, 223, 224 and optical regenerator 225, an optional opticallayer server 229 (e.g., path computation engine which is typically partof the control plane of an optical network, optical layer managementsystem), and packet switching devices 201, 202 and 203. These opticalnetwork and packet switching devices are optically and/or electricallycoupled as illustrated in this example network 200. Note, typically, thedata is communicated over optical fibers, with control signals beingcommunicated over a supervisor channel within the optical fibers and/orvia an electrical communications network (e.g., a local area network).In one embodiment, the optical control layer includes optical layerserver 229 which performs operations, such as, but not limited tocomputing light paths through optical network 200 based on registeredoptical interface characteristics, network management functions (e.g.,optical network configuration, topology, monitoring and maintainingfunctions, etc.). In one embodiment, the optical control layer includescontrol processors of one or more, and possibly all, of optical networkappliances 221-224. In one embodiment, the optical control layerincludes control processors of one or more, and possibly all, of opticalnetwork appliances 221-224 as well as optical layer server 229. Afterhaving registered their optical characteristics, including possiblyregistering alternative characteristics, the optical control layer(whether within optical layer server 229 and/or distributed amongoptical network appliances 221-224) can determine compatible light pathsthrough the optical network, and inform the optical devices (e.g.,packet switching devices 201-203, optical regenerator 225) of opticalcharacteristics to use in transmitting and/or receiving data.

For example, initially packet switching devices 201-203 and opticalregenerator 225 each register their optical characteristics with theoptical control layer of the optical network. As part of a firstexample, packet switching device 201 requests, from the optical controllayer, a connection with packet switching device 202. Optical controllayer determines a light path through optical network appliances 221,222 and 223, and informs packet switching devices 201 and 202 of whatoptical characteristics to use in sending and receiving data, includingpossibly what wavelength(s). As part of a second example, packetswitching device 201 requests, from the optical control layer, aconnection with packet switching device 203. Optical control layerdetermines a light path through optical network appliances 221, 222,223, and 224 and determines that optical regeneration is required. Theoptical control layer informs packet switching devices 201 and 203 aswell as optical regenerator 225 of what optical characteristics to usein sending and receiving data, including possibly what wavelength(s),and initiates optical network appliances 221, 222, 223 and 224 toconfigure the determined light path between packet switching devices 201and 203 through optical regenerator 225.

The list of communications capabilities that are possibly registered isextensible, and may typically include, but is not limited to, range oftransmitted power, frequency characteristics, range of valid inputpower, supported wavelength characteristics, optical layer output power,wavelength characteristics, frequency characteristics, bit rate,modulation format, forward error correction type, signal format, andframe format characteristics. Additionally, a device may registeralternatives supported by the device, possibly identifying defaultcharacteristics, and may possibly negotiate with the optical controllayer of the optical network of optical characteristics to use incommunicating over a light path through the optical network. Examples ofprotocols that can be extended to be used or directly be used incommunication between a device (internal to or external to an opticalnetwork) and the optical control layer of an optical network include,but are not limited to, Link Management Protocol (LMP), XML, TL/1,Corba. The operation of one embodiment will be described in relation toeach of the flow diagrams of FIGS. 4A, 4B, 5A and 5B describedhereinafter.

FIG. 3 illustrates a block diagram of a system or component 300 used inone embodiment associated with registration of device characteristicswith optical layer for use in establishing connections through anoptical network. In one embodiment, system or component 300 performs oneor more processes corresponding to one of the flow diagrams illustratedor otherwise described herein. In one embodiment, system or component300 is used in a network device as part of the optical control layer,and/or is part of an optical layer server. In one embodiment, system orcomponent 300 is used in a packet switching device for use incommunicating with an optical control layer for registering andestablishing what communication characteristics to use for a particularconnection.

In one embodiment, system or component 300 includes a processing element301, memory 302, storage devices 303, specialized components 305 (e.g.optimized hardware such as for performing operations, etc.), andinterface(s) 307 for communicating information (e.g., communicatinginformation over electrical and/or optical networks, user-interfaces,displaying information, etc.), which are typically communicativelycoupled via one or more communications mechanisms 309, with thecommunications paths typically tailored to meet the needs of theapplication.

Various embodiments of component 300 may include more or less elements.The operation of component 300 is typically controlled by processingelement 301 using memory 302 and storage devices 303 to perform one ormore tasks or processes. Memory 302 is one type ofcomputer-readable/computer-storage medium, and typically comprisesrandom access memory (RAM), read only memory (ROM), flash memory,integrated circuits, and/or other memory components. Memory 302typically stores computer-executable instructions to be executed byprocessing element 301 and/or data which is manipulated by processingelement 301 for implementing functionality in accordance with anembodiment. Storage devices 303 are another type of computer-readablemedium, and typically comprise solid state storage media, disk drives,diskettes, networked services, tape drives, and other storage devices.Storage devices 303 typically store computer-executable instructions tobe executed by processing element 301 and/or data which is manipulatedby processing element 301 for implementing functionality in accordancewith an embodiment.

FIG. 4A illustrates a process used in one embodiment of a device withone or more optical interfaces (e.g., a packet switching appliance,optical regenerator) configured for registering of its optical interfacecharacteristics with the optical layer of an optical network for use inestablishing connections through the optical network. Processing beginswith process block 400. In process block 402, the device and/or itsoptical interfaces are initialized, thus connecting to, or becoming partof, the optical network. In process block 404, the device registersitself with the optical control layer of the optical network. Asdetermined in process block 405, when the device has an opticalinterface to register with the optical control layer of an opticalnetwork (e.g., an optical interface is added to the device, isinitialized, or otherwise becomes available), then process block 406 isperformed. In process block 406, the device registers its communicationscapabilities, possibly including alternative configuration settings, ofone or more of its optical interfaces with the optical control layer ofan optical network for use by the optical control layer in determiningcompatible light paths through the optical network. The list ofcommunications capabilities that are possibly registered is extensible,and may typically include, but is not limited to, range of transmittedpower, frequency characteristics, range of valid input power, supportedwavelength characteristics, optical layer output power, wavelengthcharacteristics, frequency characteristics, bit rate, modulation format,forward error correction type, signal format, and frame formatcharacteristics. Processing of one embodiment then returns to processblock 405.

FIG. 4B illustrates a process used in one embodiment of an opticalcontrol layer of an optical network. Processing begins with processblock 430. As determined in process block 431, in response to a receivedregistration message (e.g., of a device and/or one or more of itsoptical interfaces), then processing proceeds to process block 432. Inone embodiment, this information is received over an optical network(e.g., over a supervisor wavelength). In one embodiment, thisinformation is received over an out-of-band network. In process block432, the optical control layer updates one or more data structures ofthe received device and/or registered communications capabilities of oneor more of the device's optical interfaces. As determined in processblock 433, if the device should advertise the registered information toother devices that are part of the optical control layer, then inprocess block 434, the device advertises (e.g., using IGP or anotherprotocol) the registered information. In this manner, the configurationinformation is proliferated among multiple devices that are part of theoptical control layer such that the optical control layer has moreinformation when determining a light path through the optical network.In one embodiment, this information is not advertised, and the opticalcontrol layer makes hop-by-hop decisions when determining and/orconfiguring a light path through the optical network. Processing of theflow diagram illustrated in FIG. 4B returns to process block 431.

FIG. 5A illustrates a process used in one embodiment of a device (e.g.,packet switching device) requesting a light path through an opticalnetwork. Processing begins with process block 500, and in process block502, a device makes a request (e.g., via Resource Reservation Protocol(RSVP) or another protocol) to the optical control layer of an opticalnetwork for a connection between one or more of its optical interfacesand another device attached to the optical network. In one embodiment,the connection request is sent over the optical network, such as over asupervisory channel. In one embodiment, the connection request isreceived over an out-of-band network. As determined in process block505, if the acknowledgement message from the optical control layer, inresponse to the connection request, includes selected configurationinformation (e.g., a selection of the previously registeredalternatives), then in process block 506, the device configures itsoptical interface(s) to operate according to the selections receivedfrom the optical control layer. In process block 508, the interfaces tothe optical network operate according to their configuration. Processingof the flow diagram illustrated in FIG. 5A is complete as indicated byprocess block 509.

FIG. 5B illustrates a process performed by the optical control layer ofan optical network in one embodiment. Processing begins with processblock 530. As determined in process block 531, in response to receivinga connection request, processing proceeds to perform process blocks532-536. In process block 532, the optical control layer attempts todetermine a feasible light path through the optical network that iscompatible with the endpoints of the light path based on information(e.g., communication capabilities, including possible alternativeconfigurations) registered with it about the endpoint equipment andpossibly optical regenerating equipment. This determination is alsotypically based on path constraints, impairments along the path, fiberand node characteristics, available optical regeneration device(s) andclient interface(s), available wavelengths, etc. Note, the extensiblelist of possible registered communications characteristics include, butare not limited to, range of transmitted power, frequencycharacteristics, range of valid input power, supported wavelengthcharacteristics, optical layer output power, wavelength characteristics,frequency characteristics, bit rate, modulation format, forward errorcorrection type, signal format, and frame format characteristics.

By having the devices register the communication capabilities of theiroptical interfaces with the optical control layer, the optical controllayer can acquire the information directly from the equipment whichallows dynamic updates of the actual capabilities of the opticalequipment connected to an optical network (e.g., in response to thechange-out of equipment and/or interfaces) as well as an understandingof the particulars of the implementation of the equipment and/or itsinterfaces, which, for example, may vary among manufactures, versions,or even different units with the same manufacturer and version ofequipment. Note, in one embodiment, equipment within the optical network(e.g., optical regenerators) also registers their capabilities with theoptical control layer, so that it knows of the capabilities of itsnetwork, and can provision light paths accordingly. Additionally, byhaving the network devices, inside and/or outside the optical network,register their communication capabilities with the optical controllayer, the optical control layer can determine light paths based onactual characteristics of the devices, rather than generalizedcharacterizations of equipment.

Next, in process block 534, the light path, determined based on theregistered information of the actual devices, is configured through theoptical network. In process block 536, the requesting device andpossibly other endpoint is notified of the light path. In oneembodiment, this notification includes parameters for configuring thenetwork devices (e.g., one or more selections of the device'salternative configurations previously registered with the opticalcontrol layer). Processing of the flow diagram illustrated in FIG. 5Breturns to process block 531.

In view of the many possible embodiments to which the principles of ourinvention may be applied, it will be appreciated that the embodimentsand aspects thereof described herein with respect to thedrawings/figures are only illustrative and should not be taken aslimiting the scope of the invention. For example, and as would beapparent to one skilled in the art, many of the process block operationscan be re-ordered to be performed before, after, or substantiallyconcurrent with other operations. Also, many different forms of datastructures could be used in various embodiments. The invention asdescribed herein contemplates all such embodiments as may come withinthe scope of the following claims and equivalents thereof.

What is claimed is:
 1. An optical device, comprising: an opticalinterface configured for coupling with an optical fiber forcommunicating information using wavelength-division multiplexing (WDM)with an optical network, including over a feasible light path, with theoptical interface being characterized by a plurality of communicationcapabilities of an optical transmitter of the optical interface, whereinsaid communication capabilities include optical layer transmissioncharacteristics for the optical transmitter; and a controller configuredto register with an optical layer server including an optical pathcomputation engine or optical network management system for computingand configuring the feasible light path through the optical network,external to the optical device, of said communication capabilities ofthe optical interface for use in the optical layer server configuringthe optical layer network to determine and route compatible signals withthe optical device through the optical network.
 2. The optical device ofclaim 1, wherein the optical interface includes configurable alternativevalues of said communication capabilities; wherein the optical device isconfigured to receive an identification of parameters according to saidconfigurable alternative values from an optical control layer outsidethe optical device; and wherein the optical device is configured toconfigure the optical interface to operate according to said receivedparameters for communicating over the optical fiber.
 3. The opticaldevice of claim 2, wherein said optical control layer is distributedamong a plurality of optical appliances in the optical network.
 4. Theoptical device of claim 3, wherein the optical device receives theidentification of parameters according to said configurable alternativevalues from the optical control layer in one of the plurality of opticalappliances, different from the optical device, in the optical network.5. The optical device of claim 2, wherein said optical control layerincludes a centralized optical layer server.
 6. The optical device ofclaim 1, wherein said communication capabilities that are said informedto the optical control layer for the optical transmitter include a rangeof transmitted power and frequency characteristics.
 7. The opticaldevice of claim 1, wherein said communication capabilities that are saidinformed to the optical control layer for the optical transmitterinclude bit rate, modulation format, forward error correction type,signal format, or frame format characteristics.
 8. The optical device ofclaim 1, wherein the optical device is a router appliance.
 9. An opticaldevice, comprising: an optical interface configured for coupling with anoptical fiber for communicating information using wavelength-divisionmultiplexing (WDM) with an optical network including over a feasiblelight path, with the optical interface being characterized by aplurality of communication capabilities of a receiver of the opticalinterface, wherein said communication capabilities include optical layerreceiving characteristic for the optical receiver; and a controllerconfigured to register with an optical layer server including an opticalpath computation engine or optical network management system forcomputing and configuring the feasible light path through the opticalnetwork, external to the optical device, of said communicationcapabilities of the optical interface for use in the optical layerserver configuring the optical layer network to determine and routecompatible signals with the optical device through the optical network.10. The optical device of claim 9, wherein the optical interfaces hasconfigurable alternative values of said communication capabilities;wherein the optical device is configured to receive an identification ofparameters according to said configurable alternative values from theoptical an optical control layer outside the optical device; and whereinthe optical device is configured to configure the optical interface tooperate according to said received parameters for communicating over theoptical fiber.
 11. The optical device of claim 10, wherein said opticalcontrol layer is distributed among a plurality of optical appliances inthe optical network.
 12. The optical device of claim 9, wherein theoptical server is configured to perform path computations within theoptical network based on optical characteristics registered with theoptical server including said communication capabilities of the opticalinterface.
 13. The optical device of claim 9, wherein said communicationcapabilities that are said informed to the optical control layer for theoptical receiver include a range of valid input power and supportedwavelength characteristics.
 14. The optical device of claim 9, whereinsaid communication capabilities that are said informed to the opticalcontrol layer for the optical receiver include bit rate, modulationformat, forward error correction type, signal format, or frame formatcharacteristics.
 15. An optical device, comprising: an optical networkinterface coupled to an optical network including a plurality of networkappliances, wherein each of the plurality of network appliances includesone or more particular optical interfaces configured for coupling withthe optical network for communicating information usingwavelength-division multiplexing (WDM), with each of said one or moreparticular optical interfaces being characterized by a plurality ofcommunication capabilities of its optical transmitter or receiver, withsaid communication capabilities including optical layer transmissioncharacteristics for said optical transmitter and optical layer receivingcharacteristics for said optical receiver; wherein the optical device isconfigured to determine compatible light paths through the opticalnetwork optically communicatively coupling one or more pairs of networkappliances of the plurality of network appliances based on receivedcommunication capabilities of said optical interfaces of the pluralityof network appliances, and to cause the optical network to provide saidat least one of said determined compatible light paths in response tosaid determining compatible light paths through the optical network. 16.The optical device of claim 15, wherein said communication capabilitiesthat are said received from each of the plurality of network appliancesinclude one or more of a group of communication capabilities consistingof: range of transmitted power, range of valid input power, andsupported wavelength characteristics.
 17. A method, comprising:receiving, by an optical control layer of an optical network from eachparticular network device of a plurality of network devicescommunicatively coupled with the optical network, a registration of aplurality of selectable communication capabilities of the opticaltransmitters and optical receivers for communicating information by saidparticular network device over the optical network usingwavelength-division multiplexing (WDM), with said communicationcapabilities including optical layer transmission characteristics for anoptical transmitter and optical layer receiving characteristics for anoptical receiver; determining, by the optical control layer, a feasiblelight path through the network based on compatible communicationscapabilities for communicating with each other over the optical networkof two particular network devices of the plurality of network devicesfrom said registered selectable communication capabilities of said twoparticular network devices; and communicating, by the optical controllayer, respective said compatible communications capabilities to each ofsaid two particular network devices for configuration by said twoparticular network devices for communicating over the feasible lightpath.
 18. The method of claim 17, comprising: causing the opticalnetwork to provide a compatible light path through the optical networkbetween said two particular network devices.
 19. The method of claim 18,wherein said causing the optical network to provide a compatible lightpath through the optical network between said two particular networkdevices includes causing the optical network to provide said compatiblelight path through an optical regenerator.
 20. The method of claim 19,wherein the plurality of network devices includes the opticalregenerator; and wherein the method comprises: selecting compatiblecommunications capabilities of the optical regenerator from saidregistered selectable communication capabilities of the opticalregenerator for said two particular network devices to communicate overthe optical network.